Apparatus for modeling three-dimensional object and method for modeling three-dimensional object

ABSTRACT

Provided is an apparatus for modeling a three-dimensional object configured to model a three-dimensional object by a fused deposition modeling, including a plurality of material resin supply units configured to supply filaments to be used as a modeling material, respectively, a mixed resin ejection unit configured to eject a mixed resin, which is obtained by mixing the filaments to be supplied from the supply units, and a control unit configured to control amounts of the filaments to be supplied from each of the supply units to the ejection unit. The supply units are configured to supply the filaments of different colors to the ejection unit, respectively, and the control unit is configured to control the amounts of the filaments to be supplied from each of the supply units to the ejection unit, thereby adjusting a color of the mixed resin that is to be ejected by the ejection unit.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application claims priority from Japanese Patent ApplicationNo. 2014-228916, filed on Nov. 11, 2014, the entire contents of whichare incorporated herein for all purpose by this reference.

TECHNICAL FIELD

The disclosure relates to an apparatus for modeling a three-dimensionalobject and a method for modeling a three-dimensional object.

DESCRIPTION OF THE BACKGROUND ART

In the related art, a method for modeling a three-dimensional object bya fused deposition modeling method (FDM) has been known (for example,refer to Patent Literature 1). The fused deposition modeling method is amodeling method developed by a Stratasys company of U.S.A. in the late1980s, in which the modeling is performed by fusing, extruding anddepositing windings of a thermoplastic resin referred to as a filamentat high temperatures of about 200° C.

[Patent Literature 1] U.S. Pat. No. 8,815,141.

SUMMARY

In the related art, as the filament that is used in the fused depositionmodeling method, filaments having a variety of colors are used. However,according to the fused deposition modeling method, the modeling isgenerally performed using only a filament of preselected one colorbecause of a configuration of an apparatus. For this reason, whenmodeling a three-dimensional object for which a coloring is performedwith two or more colors, it is necessary to once stop an operation ofthe apparatus during the modeling and to replace the filament with afilament of another color.

However, much labors and time are required to replace the filaments.Also, when replacing the filaments during the modeling, the modelingprecision may be deteriorated due to the break of the operation. Forthis reason, when performing the modeling by the fused depositionmodeling method, the colors to be colored are generally limited. As aresult, when performing the modeling by the fused deposition modelingmethod, if a coloring is required, it is general to polish athree-dimensional object after the modeling and then to perform thecoloring.

In recent years, as utilities of an apparatus (for example, 3D printer)for modeling a three-dimensional object are expanded, it is required toperform the coloring during the modeling, not after the modeling, inmany cases. Regarding the utility, it is considered to perform themodeling with color inks by using inkjet heads, for example.

In this case, however, it is necessary to use a plurality of inkjetheads, each of which has a plurality of (for example, 100 or more)precise nozzles formed therein, in conformity to the number of colors tobe used in the coloring. For this reason, the cost of the apparatusconsiderably increases, as compared to the apparatus configured toperform the modeling by the fused deposition modeling method, forexample.

For this reason, a configuration capable of more appropriately modelinga colored three-dimensional object is needed. More specifically, forexample, a configuration capable of more appropriately modeling acolored three-dimensional object by the fused deposition modeling methodcapable of performing the modeling at relatively low cost is needed.Therefore, the disclosure provides an apparatus for modeling athree-dimensional object and a method for modeling a three-dimensionalobject capable of solving the above problems.

The inventors first considered performing the modeling by the fuseddeposition modeling method by using a plurality of filaments of whichcolors are respectively different. Also, the inventors consideredmounting a plurality of heating extrusion apparatuses configured toextrude the filaments, in conformity to the number of colors to be used,as a configuration of an apparatus for modeling a three-dimensionalobject.

As a result of the intensive studies, however, the inventors found thatit is difficult to appropriately perform the coloring just by adoptingthe plurality of heating extrusion apparatuses. More specifically, forexample, when the plurality of heating extrusion apparatuses is simplyused, it is possible to switch the colors within a range of the numberof filaments to be used. In this case, however, it is difficult toappropriately express an intermediate color obtained by mixing aplurality of colors, for example. For this reason, when expressing avariety of colors to a certain level or higher, it is required to use avery large number of filaments. In this case, the cost of the apparatusconsiderably increases. Also, according to this configuration, since theheating extrusion apparatus being used is replaced upon the switch ofthe colors, the modeling precision may be deteriorated due to adifference of ejection characteristics, for example.

Regarding this, the inventors further intensively studied and consideredmixing and adjusting resins of a plurality of colors to a desired colorin advance, not using the plurality of heating extrusion apparatuses,and extruding the adjusted resin to perform the modeling. According tothis configuration, it is possible to more appropriately express themore diverse colors. Also, since the ejection characteristics are notchanged upon the switch of the colors, the modeling precision is notdeteriorated due to the switch of the colors. That is, the disclosurehas following configurations.

(Configuration 1) There is provided an apparatus for modeling athree-dimensional object configured to model a three-dimensional objectby a fused deposition modeling method. The apparatus includes aplurality of material resin supply units configured to supply a materialresin, which is a resin to be used as a modeling material, respectively;a mixed resin ejection unit configured to eject a mixed resin, which isa resin obtained by mixing the material resins to be supplied from theplurality of material resin supply units, and a resin supply controlunit configured to control amounts of the material resins to be suppliedfrom each of the plurality of material resin supply units to the mixedresin ejection unit. The plurality of material resin supply units isconfigured to supply the material resins of different colors to themixed resin ejection unit, respectively. The resin supply control unitis configured to control the amounts of the material resins to besupplied from each of the plurality of material resin supply units tothe mixed resin ejection unit, thereby adjusting a color of the mixedresin that is to be ejected by the mixed resin ejection unit.

According to the above configuration, it is possible to appropriatelymodel the three-dimensional object at low cost by performing themodeling by the fused deposition modeling method, for example. Also, itis possible to appropriately model the colored three-dimensional objectby using the plurality of types of material resins of which colors arerespectively different. Also, in this case, it is possible toappropriately express a variety of colors by mixing the plurality oftypes of material resins before the ejection, without being limited tothe colors of the material resins. Also, it is possible to change thecolor while continuing to eject the mixed resin obtained by mixing thematerial resins. For this reason, the modeling precision is notdeteriorated due to the switch of the colors. Therefore, according tothe above configuration, it is possible to appropriately model thecolored three-dimensional object at low cost.

Here, the material resin that is to be supplied by each material resinsupply unit is a thread-shaped or fine line-shaped resin, for example.As the material resin, a well-known filament that is used in the fuseddeposition modeling method may be used. Also, regarding the operation ofthe mixed resin ejection unit, the description “ejection of the mixedresin” means an ejection operation that is to be performed when modelinga three-dimensional object by the fused deposition modeling method.

Also, the mixed resin ejection unit is configured to mix the materialresins while heating the material resins supplied from each of thematerial resin supply units to about 200° C., for example. The mixedresin ejection unit is configured to eject the mixed resin obtained bythe mixing from the nozzle, thereby performing the modeling by the fuseddeposition modeling method. As the mixed resin ejection unit, a mixingnozzle may be used, for example.

(Configuration 2) The material resin is a thermoplastic resin. The mixedresin ejection unit includes a heater unit configured to heat thematerial resins to be supplied from each of the material resin supplyunits, a resin mixing unit configured to mix the material resins heatedby the heater unit, thereby generating the mixed resin, and a nozzleconfigured to eject the mixed resin generated at the resin mixing unit.The mixed resin ejection unit is configured to eject the mixed resinfrom the nozzle, thereby modeling the three-dimensional object.

According to the above configuration, it is possible to appropriatelymix the material resins in the mixed resin ejection unit. Also, themixed resin, which is obtained by the mixing with being heated, isejected, so that it is possible to appropriately model thethree-dimensional object by the mixed resin having a desired color.

(Configuration 3) The resin supply control unit is configured to controlthe amounts of the material resins to be supplied to the mixed resinejection unit so that a total amount of the material resins to besupplied from the plurality of material resin supply units to the mixedresin ejection unit is matched with a preset supply amount.

According to the above configuration, it is possible to moreappropriately mix the material resins in the mixed resin ejection unit,for example. Also, in this configuration, the mixed resin ejection unitis configured to eject the mixed resin from the nozzle at an ejectionamount corresponding to the supplied material resins. In this case, theejection amount from the nozzle is an ejection amount per unit time. Forthis reason, according to the above configuration, it is also possibleto stabilize the ejection amount from the nozzle to a constant amountcorresponding to the supply amounts of the material resins. Thereby, itis also possible to model the three-dimensional object with higherprecision, for example.

In the meantime, when the supply amount of the material resin from anyone material resin supply unit is increased, for example, the resinsupply control unit decreases the supply amounts of the material resinsfrom the other material resin supply units, in correspondence to theincrease. Also, the supply amount of the material resin from any onematerial resin supply unit is decreased, for example, the resin supplycontrol unit increases the supply amounts of the material resins fromthe other material resin supply units, in correspondence to thedecrease. According to this configuration, for example, it is possibleto appropriately set a total amount of the material resins to besupplied to the mixed resin ejection unit to a predetermined supplyamount.

(Configuration 4) The apparatus includes the plurality of material resinsupply units configured to supply the material resins of respectivecolors of at least yellow, magenta, cyan and black. According to thisconfiguration, for example, it is possible to more appropriately performthe coloring with diverse colors. More specifically, in this case, it isconsidered to perform the full-color coloring, for example. According tothis configuration, it is possible to appropriately provide an apparatus(full-color modeling machine) configured to perform a full-colormodeling at low cost.

(Configuration 5) The material resin supply unit configured to supplythe material resin of a white color is further provided. According tothis configuration, for example, it is possible to more appropriatelyperform the coloring with diverse colors. The material resin of a whitecolor may be used to express a light color, for example.

(Configuration 6) The material resin supply unit configured to supplythe material resin of a clear color is further provided. According tothis configuration, it is possible to further express a transparentcolor, in addition to the colors to be expressed by the material resinsof respective colors of yellow, magenta, cyan, and black. For thisreason, according to this configuration, for example, it is possible tomore appropriately perform the coloring with more diverse colors.

(Configuration 7) Each of the plurality of material resin supply unitshas a resin extrusion device configured to extrude the material resintowards the mixed resin ejection unit by a roller. The resin supplycontrol unit is configured to control rotation numbers of the rollers ofthe resin extrusion devices of the plurality of material resin supplyunits, thereby controlling the amounts of the material resins to besupplied from each of the plurality of material resin supply units tothe mixed resin ejection unit.

According to the above configuration, for example, it is possible tomore appropriately mix the material resins. Thereby, it is also possibleto more appropriately model the colored three-dimensional object. Also,the resin supply control unit is configured to control the rotationnumbers of the rollers of the respective resin extrusion devices, inaccordance with color information indicating a color of the mixed resinto be ejected from the nozzle at each timing, for example. In this case,the resin supply control unit is configured to acquire the colorinformation on the basis of data representing a three-dimensional objectto be modeled, for example.

Also, the resin supply control unit is configured to control therotation numbers of the rollers of the resin extrusion devices, takinginto consideration a time difference between the timing at which thematerial resins are mixed and the timing at which the mixed resin isejected from the nozzle. In this case, the time difference is a timedifference that is to be determined depending on a capacity of the mixedresin ejection unit, for example. Also, the resin supply control unitmay be configured to once stop the ejection, in conformity to the timingat which the color of the mixed resin to be ejected from the nozzle ofthe mixed resin ejection unit is changed, for example. By thisconfiguration, it is possible to more appropriately change the color,for example.

(Configuration 8) There is provided a method for modeling athree-dimensional object by a fused deposition modeling method. Themethod uses a plurality of material resin supply units configured tosupply a material resin, which is a resin to be used as a modelingmaterial, respectively, and a mixed resin ejection unit configured toeject a mixed resin, which is a resin obtained by mixing the materialresins to be supplied from the plurality of material resin supply units.The plurality of material resin supply units is configured to supply thematerial resins of different colors to the mixed resin ejection unit,respectively. The method includes controlling amounts of the materialresins to be supplied from each of the plurality of material resinsupply units to the mixed resin ejection unit, thereby adjusting a colorof the mixed resin that is to be ejected by the mixed resin ejectionunit. According to this configuration, it is possible to accomplish thesame effects as the configuration 1, for example.

According to the disclosure, it is possible to appropriately model thecolored three-dimensional object.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 depicts an example of an apparatus 10 for modeling athree-dimensional object according to an illustrative embodiment of thedisclosure.

DETAILED DESCRIPTION OF EMBODIMENTS

Hereinafter, an illustrative embodiment of the disclosure will bedescribed with reference to the drawings. FIG. 1 depicts an example ofan apparatus 10 for modeling a three-dimensional object according to anillustrative embodiment of the disclosure. In this illustrativeembodiment, the apparatus 10 for modeling a three-dimensional object isan apparatus for modeling a three-dimensional object configured to modela three-dimensional object by a fused deposition modeling method. Inthis case, the fused deposition modeling method is a method of extrudingresins, which are fused by the heating, from nozzles and depositing thesame to model a three-dimensional object.

More specifically, the apparatus 10 for modeling a three-dimensionalobject is configured to perform the modeling by using a filament, whichis a thread-shaped or fine line-shaped resin, as a material resin thatis a resin to be used as a modeling material. Also, the apparatus 10 formodeling a three-dimensional object is configured to model a coloredthree-dimensional object by using a plurality of types of filaments ofwhich colors are respectively different. Also, the apparatus 10 formodeling a three-dimensional object of this illustrative embodiment mayhave the same or similar features as or to a well-known apparatusconfigured to perform the modeling by the fused deposition modelingmethod, except for configurations to be described later.

Also, in this illustrative embodiment, the apparatus 10 for modeling athree-dimensional object has a plurality of material resin supply units14, a mixed resin ejection unit 12, a scanning driving unit 16, a standunit 18, and a control unit 20. The plurality of material resin supplyunits 14 is supply units configured to supply filaments 52, which are anexample of the material resin. In this illustrative embodiment, each ofthe plurality of material resin supply units 14 is configured to supplythe filaments 52 of different colors to the mixed resin ejection unit12, respectively.

Also, more specifically, in this illustrative embodiment, the pluralityof material resin supply units 14 is configured to supply the filaments52 of respective colors of Y (yellow), M (magenta), C (cyan), K (black),W (white) and CL (clear) to the mixed resin ejection unit 12,respectively. The CL (clear) color is an achromatic transparent color.Also, the respective colors of YMCK are used as solid colors when mixingwith the W color or CL color. Also, in a modified embodiment of theconfiguration of the apparatus 10 for modeling a three-dimensionalobject, a material resin supply unit 14 configured to supply a filament52 of a color except for the above colors may be further provided. Also,a part of the material resin supply units 14 may be omitted depending ona quality required for the three-dimensional object 50. For example, thematerial resin supply unit 14 as regards at least one of W and CL colorsmay be omitted.

Also, in this illustrative embodiment, each of the material resin supplyunits 14 has a filament feeding unit 112 and a filament extrusion roller114. The filament feeding unit 112 is a unit configured to sequentiallyfeed the filament 52 in accordance with an operation of the filamentextrusion roller 114. More specifically, the filament feeding unit 112may be a holder having the filament 52 wound into a winding shape.

The filament extrusion roller 114 is an example of the resin extrusiondevice, and is configured to sequentially feed the filament 52 from thefilament feeding unit 112 towards the mixed resin ejection unit 12 inaccordance with an instruction of the control unit 20. Also, in thisillustrative embodiment, the filament extrusion roller 114 has aconfiguration of extruding the filament 52 by a roller contacting thefilament 52, is arranged at a more upstream side (primary side) on asupply path of the filament 52 than the mixed resin ejection unit 12,and is configured to sequentially feed the filament 52 towards the mixedresin ejection unit 12 by rotating the roller in a direction shown withan arrow in FIG. 1. By the above configuration, in this illustrativeembodiment, each of the plurality of material resin supply units 14extrudes the filaments 52 of respective colors towards the mixed resinejection unit 12 in accordance with the instruction of the control unit20, respectively.

As shown in FIG. 1, in this illustrative embodiment, each material resinsupply unit 14 is configured to press the filament 52 of each color intothe mixed resin ejection unit 12 through a separate path. Also, eachmaterial resin supply unit 14 preferably has a tube for passing thefilament 52 towards the mixed resin ejection unit 12, for example.According to this configuration, it is possible to more appropriatelysupply the filament 52 through the tube.

Also, in this illustrative embodiment, the filament 52 of each color isa thermoplastic resin. As the filament 52, it is possible to favorablyuse a resin that is to be fused at temperatures of about 200° C., forexample. Also, as the filament 52 of each color, it is possible tofavorably use a well-known filament that is to be used in the fuseddeposition modeling method, for example.

The mixed resin ejection unit 12 is an ejection unit configured to ejectthe fused resin to a position at which the three-dimensional object 50is to be formed. In this case, the position at which thethree-dimensional object 50 is to be formed is a position at which theresin is to be extruded upon the modeling by the fused depositionmodeling method, for example.

Also, in this illustrative embodiment, the mixed resin ejection unit 12has a heater unit 102 and a mixing nozzle 104. The heater unit 102 is aheating unit configured to heat the filaments 52 supplied from therespective material resin supply units 14, and is configured to receiveand heat the filaments 52 supplied from the plurality of material resinsupply units 14, thereby fusing the respective filaments 52. In thiscase, the heater unit 102 is configured to heat the filaments 52 toabout 200° C. (for example, about 180° C. to 250° C.), depending on thefusing temperatures of the filaments 52, for example. Also, the heaterunit 102 is configured to sequentially receive the filaments 52 from theplurality of material resin supply units 14 and to sequentially send outthe resins obtained by fusing the filaments 52 to the mixing nozzle 104.

The mixing nozzle 104 is a member configured to mix and eject the resinssupplied from the heater unit 102. As the mixing nozzle 104, awell-known small mixing nozzle can be favorably used, for example. Also,in this illustrative embodiment, the mixing nozzle 104 has a resinmixing unit 202 and a nozzle 204. The resin mixing unit 202 is a partconfigured to receive the resins heated by the heater unit 102. Also, inthis illustrative embodiment, the resin mixing unit 202 is configured sothat a diameter thereof gradually decreases towards the tip nozzle 204.For this reason, the resins supplied from the heater unit 102 aregradually mixed in the resin mixing unit 202 on a path facing towardsthe nozzle 204. Also, the resin mixing unit 202 is configured to therebygenerate a mixed resin, which is the resin obtained by mixing thefilaments 52 heated by the heater unit 102.

Also, the nozzle 204 is an opening of the resin mixing unit 202 providedat a position facing the three-dimensional object 50, and is configuredto eject the mixed resin towards a position at which thethree-dimensional object 50 is to be formed. Thereby, the mixed resinejection unit 12 is configured to heat the filaments 52 in the heaterunit 102, which are supplied from the plurality of material resin supplyunits 14. Also, the mixed resin ejection unit 12 is configured to mixthe heated and fused filaments 52 in the mixing nozzle 104 just beforeejecting the mixed resin from the nozzle 204 towards thethree-dimensional object 50 (just before the ejection). Then, the mixedresin ejection unit 12 is configured to eject the mixed resin generatedby the mixing from the nozzle 204 of the mixing nozzle 104. Also, inthis case, the mixed resin ejected from the nozzle 204 with being fusedis cooled and solidified by the surrounding air.

The scanning driving unit 16 is a driving unit configured to move themixed resin ejection unit 12 relative to the three-dimensional object50, and is configured to enable the mixed resin ejection unit 12 toperfoiiii the scanning of ejecting the fused mixed resin and movingrelative to the three-dimensional object 50, thereby enabling the mixedresin ejection unit 12 to eject the mixed resin to respective parts ofthe three-dimensional object 50. In this case, the scanning driving unit16 is configured to move at least one of the mixed resin ejection unit12 and the stand unit 18, thereby enabling the mixed resin ejection unit12 to perform the scanning.

More specifically, the scanning driving unit 16 is configured to enablethe mixed resin ejection unit 12 to perform the scanning in apredetermined XY plane, in accordance with an instruction of the controlunit 20, for example. The XY plane is a plane parallel with an uppersurface of the stand unit 18, for example. Thereby, the scanning drivingunit 16 enables the mixed resin ejection unit 12 to form one layer of aplurality of layers to be deposited so as to configure thethree-dimensional object 50.

Also, the scanning driving unit 16 is configured to move the mixed resinejection unit 12 relative to the three-dimensional object 50 in adirection of separating from the three-dimensional object 50 in a Zdirection perpendicular to the XY plane, in accordance with aninstruction of the control unit 20, for example, whenever the mixedresin ejection unit 12 forms one layer. Thereby, a distance between thethree-dimensional object 50 and the mixed resin ejection unit 12 isadjusted to a distance for forming a next layer. By repeating the aboveoperations, the scanning driving unit 16 enables the mixed resinejection unit 12 to perform the scanning for forming a plurality oflayers in conformity to a shape of the three-dimensional object 50 to bemodeled.

The stand unit 18 is a stand-shaped member configured to hold thethree-dimensional object 50 being modeled. In this illustrativeembodiment, the stand unit 18 is configured to hold thethree-dimensional object 50 being modeled by placing thethree-dimensional object 50 on an upper surface thereof facing the mixedresin ejection unit 12.

The control unit 20 is a central processing unit (CPU) of the apparatus10 for modeling a three-dimensional object, for example, and isconfigured to control operations of the respective units of theapparatus 10 for modeling a three-dimensional object, thereby enablingthe apparatus 10 for modeling a three-dimensional object to model thethree-dimensional object 50. Also, in this illustrative embodiment, thecontrol unit 20 is configured to operate as a resin supply control unit,too, in accordance with a program such as the firmware, for example. Inthis case, the resin supply control unit has a configuration forcontrolling amounts of the filaments 52 that are to be supplied fromeach of the plurality of material resin supply units 14 to the mixedresin ejection unit 12.

More specifically, in this illustrative embodiment, the control unit 20is configured to control amounts of the filaments 52 that are to besupplied from each of the plurality of material resin supply units 14 tothe mixed resin ejection unit 12, thereby adjusting a color of the mixedresin that is to be ejected by the mixed resin ejection unit 12. In thiscase, for example, the control unit 20 is configured to control rotationnumbers of the filament extrusion rollers 114 of the respective materialresin supply units 14, thereby controlling the amounts of the filaments52 that are to be supplied from each of the plurality of material resinsupply units 14 to the mixed resin ejection unit 12. The rotation numberof the filament extrusion roller 114 means a rotation number of theroller configured to extrude the filament 52 in the filament extrusionroller 114.

According to the illustrative embodiment, the modeling is performed bythe fused deposition modeling method, for example, so that it ispossible to appropriately model (3D model) the three-dimensional object50 at low cost. Also, it is possible to appropriately model the coloredthree-dimensional object 50 by using a plurality of types of thefilaments 52 of which colors are respectively different.

Also, in this illustrative embodiment, it is possible to appropriatelymix the plurality of types of the filaments 52 before the ejection byusing the mixed resin ejection unit 12. Also, the mixed resin obtainedby the mixing is ejected, so that it is possible to appropriately modelthe three-dimensional object by using the mixed resin adjusted to adesired color. For this reason, according to the illustrativeembodiment, for example, it is possible to appropriately express avariety of colors as regards the color of the three-dimensional object50, without being limited to the colors of the filaments 52.

Also, as described above, in this illustrative embodiment, the controlunit 20 is configured to control the amounts of the filaments 52 thatare to be supplied from each of the plurality of material resin supplyunits 14 to the mixed resin ejection unit 12. In this case, for example,it is possible to change the color while continuing to eject the mixedresin from the nozzle 204.

More specifically, in this case, the control unit 20 is configured tocontrol the rotation numbers of the filament extrusion rollers 114 ofthe respective material resin supply units 14, in accordance with colorinformation indicating a color of the mixed resin to be ejected from thenozzle 204 at each timing, for example. Thereby, the control unitcontrols a pressing amount that each filament extrusion roller 114presses the filament 52, in accordance with the color information.

According to the above configuration, it is possible to appropriatelychange the color of the mixed resin to be ejected. Also, in this case,since it is possible to change the color while continuing to eject themixed resin, it is possible to prevent the modeling precision from beingdeteriorated due to the switch of the colors. For this reason, accordingto this illustrative embodiment, for example, it is possible to moreappropriately model the three-dimensional object 50 colored with thediverse colors at low cost.

In the meantime, the control unit 20 is preferably configured to controlthe rotation numbers of the filament extrusion rollers 114, taking intoconsideration a time difference between the timing at which thefilaments 52 are mixed and the timing at which the mixed resin isejected from the nozzle 204. In this case, the time difference is a timedifference that is to be determined depending on a capacity of the mixedresin ejection unit 12, for example.

Also, the control unit 20 may once stop the ejection in conformity tothe timing at which the color of the mixed resin to be ejected from thenozzle 204 of the mixed resin ejection unit 12 is changed. Also in thiscase, since it is possible to perform the modeling by using the samemixed resin ejection unit 12 before and after the change of the color,it is possible to perform the modeling with higher precision, ascompared to a configuration where the nozzle being used is also changedwhen the color is changed, for example. For this reason, also in thiscase, it is possible to more appropriately change the color, forexample.

Here, in order to model the three-dimensional object 50 with higherprecision, it is preferably to keep an ejection amount (an ejectionamount per unit time) of the mixed resin, which is to be ejected fromthe nozzle 204 of the mixed resin ejection unit 12, to a constantejection amount. To this end, it is also preferably to constantly keep asupply amount (a supply amount per unit time) of the filaments 52 thatare to be supplied to the mixed resin ejection unit 12.

For this reason, in this illustrative embodiment, the control unit 20 isconfigured to control a total amount of the filaments 52, which are tobe supplied from the plurality of material resin supply units 14 to themixed resin ejection unit 12, in conformity to a preset supply amount.More specifically, when the supply and the like of the filament 52 fromany one material resin supply unit 14 to the mixed resin ejection unit12 is increased, for example, the control unit 20 decreases the supplyamounts of the filaments 52 from the other material resin supply units14, in correspondence to the increase. Also, when the supply amount ofthe filament 52 from any one material resin supply unit 14 is decreased,for example, the control unit 20 increases the supply amounts of thefilaments 52 from the other material resin supply units 14, incorrespondence to the decrease.

By the above configuration, for example, it is possible to appropriatelykeep the total amount of the filaments 52, which are to be supplied tothe mixed resin ejection unit 12, to a constant amount. Thereby, it isalso possible to more stabilize the ejection amount of the mixed resinfrom the nozzle of the mixed resin ejection unit 12.

Subsequently, the effects accomplished by the illustrative embodimentare described in more detail. As described above, according to theillustrative embodiment, it is possible to appropriately perform themodeling of the three-dimensional object 50 with high precision, forexample. Also, it is possible to appropriately color thethree-dimensional object 50 with the various colors by using theplurality of types of the filaments 52 having different colors. Also, inthis case, for example, it is considered to perform the full-colorcoloring by using the filaments 52 of the respective colors of YMCK.Also, in this illustrative embodiment, the modeling is performed by thefused deposition modeling method, so that it is possible toappropriately suppress the cost of the apparatus, as compared to aconfiguration where a plurality of inkjet heads is used to perform themodeling, for example. For this reason, according to the illustrativeembodiment, it is possible to appropriately provide an apparatus(full-color modeling machine) configured to perform a full-colormodeling at low cost.

Also, in this illustrative embodiment, the filaments 52 of the white andclear colors are further used, in addition to the filaments 52 of therespective colors of YMCK. In this case, the filament of the white color52 may be used to express a light color of each color, for example.Also, the filament of the white color 52 may be used to model a part forwhich the coloring is not performed or an inner area configuring aninside of the three-dimensional object 50, for example. Also, thefilament 52 of the clear color may be used to express a transparentcolor. Also, the filament 52 of the clear color may be used to model apart for which the coloring is not performed or to form a transparentlayer covering a surface of the three-dimensional object 50, forexample. Also, for example, the filament 52 of the clear color may beused to model an inner area of the three-dimensional object 50. It isalso considered to express a transparent color and a non-transparentcolor as regards each color by using the filaments 52 of the respectivecolors of YMCK and the filament 52 of the clear color.

According to this illustrative embodiment, the filament 52 except forthe respective colors of YMCK is further used, so that it is possible tomore appropriately color the three-dimensional object 50 with the morediverse colors. Also, as described above, in this illustrativeembodiment, the filaments 52 are mixed in the mixing nozzle 104 justbefore the ejection from the nozzle 204. For this reason, according tothe illustrative embodiment, for example, it is possible toappropriately change the color of the mixed resin to be ejected from thenozzle 204 with high readiness. Thereby, for example, it is possible tomore appropriately model the three-dimensional object 50 having a highdesign quality. In this case, more specifically, it is considered tomake a gradation expression by a plurality of colors, for example. Also,it is considered to make a drawing such as a preset drawing pattern witha resolution corresponding to the ejection precision of the nozzle 204.

Also, according to the illustrative embodiment, it is possible to make acolor matching more easily and appropriately. More specifically, forexample, as a method of modeling a three-dimensional object colored witha method different from the illustrative embodiment, a method ofmodeling a three-dimensional object colored using a binder in which apigment is mixed with a white plaster or a resin is considered, forexample. However, in this case, a color reproduction area is narrowed,so that the three-dimensional object is whitely expressed as a whole.

Also, as other methods of modeling a colored three-dimensional object,it is considered to color only a surface of the three-dimensional objectwith a color ink and the like, for example. In this case, however, theresolutions are different between a planar surface and an uprightsurface, so that it is very difficult to make a color matching.

In contrast, according to this illustrative embodiment, it is possibleto sufficiently widen the color reproduction area by mixing thefilaments 52 of multiple colors to express a variety of colors. Also,since the modeling is performed using the mixed resin in which thefilaments 52 of multiple colors are mixed in advance, it is possible toappropriately obtain the same color, regardless of the planar surfaceand the upright surface. For this reason, according to this illustrativeembodiment, it is possible to make the color matching more easily andappropriately. Thereby, it is also possible to more appropriately modelthe colored three-dimensional object 50.

Also, in this illustrative embodiment, the three-dimensional object ismodeled by the fused deposition modeling method, so that it is possibleto deposit the plurality of layers configuring the three-dimensionalobject 50. Thereby, it is also possible to appropriately increase themodeling speed. Also, in this case, the depositing speed of depositingthe plurality of layers depends on the diameter of the nozzle 204configured to eject the fused mixed resin. The diameter of the nozzle204 can be appropriately changed by replacing the mixing nozzle 104, forexample.

For this reason, in this illustrative embodiment, it is possible toperform the modeling at the various conditions by changing the diameterof the nozzle 204 and appropriately setting the supply amount of thematerial resin. More specifically, for example, when the nozzle 204 ismade to have a small diameter, the modeling speed decreases but thehigher-definition full-color modeling can be performed. Also, forexample, when the nozzle 204 is made to have a large diameter, themodeling definition is lowered but the modeling speed increases. Forthis reason, according to this illustrative embodiment, it is possibleto more appropriately model the colored three-dimensional object 50,depending on the quality and the like needed for the three-dimensionalobject 50. Also in this case, regarding the setting of the supply amountof the material resin, when the supply amount of the material resin fromany one material resin supply unit 14 is increased, for example, thesupply amounts of the material resins from the other material resinsupply units 14 are preferably decreased, in correspondence to theincrease. Also, when the supply amount of the material resin from anyone material resin supply unit 14 is decreased, for example, the supplyamounts of the material resins from the other material resin supplyunits 14 are preferably increased, in correspondence to the decrease. Bythis configuration, it is possible to appropriately set the total amountof the material resins to be supplied to the mixed resin ejection unit12 to a predetermined supply amount.

Although the illustrative embodiment of the disclosure has beendescribed, the technical scope of the disclosure is not limited to theillustrative embodiment. It is obvious to one skilled in the art thatthe illustrative embodiment can be variously changed or improved. It isclear from the claims that the changes or improvements can also beincluded in the technical scope of the disclosure.

INDUSTRIAL APPLICABILITY

The disclosure can be appropriately applied to the apparatus formodeling a three-dimensional object, for example.

What is claimed is:
 1. An apparatus for forming a three-dimensionalobject configured to form a three-dimensional object by a fuseddeposition modeling method, the apparatus comprising: a plurality ofmaterial resin supply units configured to supply a material resin, whichis a resin to be used as a modeling material, respectively; a mixedresin ejection unit configured to eject a mixed resin, which is a resinobtained by mixing the material resins to be supplied from the pluralityof material resin supply units; and a resin supply control unitconfigured to control amounts of the material resins to be supplied fromeach of the plurality of material resin supply units to the mixed resinejection unit, wherein the plurality of material resin supply units isconfigured to supply the material resins of different colors to themixed resin ejection unit, respectively; and wherein the resin supplycontrol unit is configured to control the amounts of the material resinsto be supplied from each of the plurality of material resin supply unitsto the mixed resin ejection unit, thereby adjusting a color of the mixedresin that is to be ejected by the mixed resin ejection unit.
 2. Theapparatus for forming a three-dimensional object according to claim 1,wherein the material resin is a thermoplastic resin, the mixed resinejection unit comprises: a heater unit configured to heat the materialresins to be supplied from each of the material resin supply units; aresin mixing unit configured to mix the material resins heated by theheater unit, thereby generating the mixed resin; and a nozzle configuredto eject the mixed resin generated at the resin mixing unit, and themixed resin is ejected from the nozzle, thereby foiming thethree-dimensional object.
 3. The apparatus for foaming athree-dimensional object according to claim 1, wherein the resin supplycontrol unit is configured to control the amounts of the material resinsto be supplied to the mixed resin ejection unit, so that a total amountof the material resins to be supplied from the plurality of materialresin supply units to the mixed resin ejection unit is matched with apreset supply amount.
 4. The apparatus for forming a three-dimensionalobject according to claim 2, wherein the resin supply control unit isconfigured to control the amounts of the material resins to be suppliedto the mixed resin ejection unit, so that a total amount of the materialresins to be supplied from the plurality of material resin supply unitsto the mixed resin ejection unit is matched with a preset supply amount.5. The apparatus for forming a three-dimensional object according toclaim 1, wherein the apparatus comprises the plurality of material resinsupply units configured to supply the material resins of respectivecolors of at least yellow, magenta, cyan and black.
 6. The apparatus forforming a three-dimensional object according to claim 5, furthercomprising: the material resin supply unit configured to supply thematerial resin of a white color.
 7. The apparatus for forming athree-dimensional object according to claim 5, further comprising: thematerial resin supply unit configured to supply the material resin of aclear color.
 8. The apparatus for forming a three-dimensional objectaccording to claim 1, wherein each of the plurality of material resinsupply units has a resin extrusion device configured to extrude thematerial resin towards the mixed resin ejection unit by a roller, andwherein the resin supply control unit is configured to control rotationnumbers of the rollers of the resin extrusion devices of the pluralityof material resin supply units, thereby controlling the amounts of thematerial resins to be supplied from each of the plurality of materialresin supply units to the mixed resin ejection unit.
 9. The apparatusfor forming a three-dimensional object according to claim 2, whereineach of the plurality of material resin supply units has a resinextrusion device configured to extrude the material resin towards themixed resin ejection unit by a roller, and wherein the resin supplycontrol unit is configured to control rotation numbers of the rollers ofthe resin extrusion devices of the plurality of material resin supplyunits, thereby controlling the amounts of the material resins to besupplied from each of the plurality of material resin supply units tothe mixed resin ejection unit.
 10. The apparatus for forming athree-dimensional object according to claim 3, wherein each of theplurality of material resin supply units has a resin extrusion deviceconfigured to extrude the material resin towards the mixed resinejection unit by a roller, and wherein the resin supply control unit isconfigured to control rotation numbers of the rollers of the resinextrusion devices of the plurality of material resin supply units,thereby controlling the amounts of the material resins to be suppliedfrom each of the plurality of material resin supply units to the mixedresin ejection unit.
 11. The apparatus for forming a three-dimensionalobject according to claim 4, wherein each of the plurality of materialresin supply units has a resin extrusion device configured to extrudethe material resin towards the mixed resin ejection unit by a roller,and wherein the resin supply control unit is configured to controlrotation numbers of the rollers of the resin extrusion devices of theplurality of material resin supply units, thereby controlling theamounts of the material resins to be supplied from each of the pluralityof material resin supply units to the mixed resin ejection unit.
 12. Amethod for forming a three-dimensional object by a fused depositionmodeling method, the method using: a plurality of material resin supplyunits configured to supply a material resin, which is a resin to be usedas a modeling material, respectively; and a mixed resin ejection unitconfigured to eject a mixed resin, which is a resin obtained by mixingthe material resins to be supplied from the plurality of material resinsupply units, the plurality of material resin supply units beingconfigured to supply the material resins of different colors to themixed resin ejection unit, respectively, the method comprising:controlling amounts of the material resins to be supplied from each ofthe plurality of material resin supply units to the mixed resin ejectionunit, thereby adjusting a color of the mixed resin that is to be ejectedby the mixed resin ejection unit.